Patterns of Necrosis In Tissues
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Transcript Patterns of Necrosis In Tissues
Necrosis
Apoptosis
Different Types of Cell Death
Term
Definition
Necrosis
Antemortem pathologic
cell death
Apoptosis
Antemortem programmed
cell death
Autolysis
Postmortem cell death
Necrosis
Spectrum of morphologic changes
that follow cell death in living tissue
• Increased eosinophilia
• Myelin figures
• Nuclear changes
Increased eosinophilia
• binding of eosin to denatured proteins causes increased
cytoplasmic eosinophilia more pink
• loss of DNA, RNA causes decreased basophilia less
blue
Myelin figures
Dead cells are replaced by large whorled
phospholipid masses
Nuclear Changes
• Karyolysis : the basophilia of chromatin fades due to
breakdown of DNA
• Pyknosis : Nuclear shrinkage and increased basophilia
• Karyorrhexis : fragmentation of the nucleus
Patterns of Necrosis In Tissues
• Coagulative necrosis: the outline of the dead cells
are maintained and the tissue is somewhat firm.
• Example: myocardial infarction
.
Patterns of Necrosis In Tissues
• Liquefactive necrosis: the dead cells undergo
disintegration and affected tissue is liquefied.
• Examples: focus of bacterial infections,
cerebral infarction.
Patterns of Necrosis In Tissues
.
• Caseous necrosis: a form of coagulative necrosis
(cheese-like).
• Example: tuberculosis lesions.
Patterns of Necrosis In Tissues
• Fat necrosis: enzymatic digestion of fat.
• Example: necrosis of fat by pancreatic enzymes.
Patterns of Necrosis In Tissues
• Gangrenous necrosis: Necrosis (secondary to
ischemia) usually with superimposed infection.
• Dry gangrene
• Wet gangrene
• Example: necrosis of distal limbs, usually foot and toes
in diabetes.
APOPTOSIS
A pathway of cell death that helps to eliminate
unwanted cells by an internally programmed series
of events effected by dedicated gene products.
Physiologic situations
During development for removal of excess cells during
• Programmed destruction of cells during embryogenesis
• To maintain cell population in tissues with high turnover of
cells, such as skin, bowels.
• Hormone-dependent involution - Endometrium, ovary, breasts
etc.
• To eliminate immune cells after cytokine depletion, and
autoreactive T-cells in developing thymus.
Pathological conditions
• During development for removal of excess cells
during
• To eliminate cells with DNA damage by radiation,
cytotoxic agents etc.
• To remove damaged cells by virus
• Cell death in tumors.
Normal cell proliferation is important for
• growth and development
• replacement of destroyed cells
Cell death is important for
• programmed death of cells not needed after a certain point in development
• removal of potentially dangerous damaged cells
Morphological changes
• shrinkage of cell volume and shape
• chromatin condensation, DNA fragmentation, and
peripheral clumping (most characteristic feature of
apoptosis)
• formation of surface blebs
• fragmentation into apoptotic bodies
• phagocytosis of apoptotic bodies by macrophages
Biochemical features
• Protein cleavage : caspases
• DNA breakdown : oligonucleosomes in multiples of 180
– 200 base pairs
• Phagocytic recognition : phosphatidylserine,
thrombospondin
SEQUENTIAL EVENTS IN APOPTOTIC CELL
DEATH
Apoptosis may be triggered by:
• cytotoxic T cells
• receptor-ligand interactions on the cell membrane
• withdrawal of growth factors or hormones
• injury (radiation, toxins, free radicals)
NECROSIS
APOPTOSIS
STIMULI
irreversible ischemia / hypoxia
cytotoxic T cells
receptor-ligand interactions
withdrawal of growth factors or hormones,
injury (radiation, toxins, free radicals)
MORPHOLOGY
cell swelling
random nuclear fragments
inflammation
cell shrinkage
specific DNA fragmentation
no inflammation
TISSUE REACTIONS
enzymatic degradation
denaturation of proteins
shrinkage of cell volume and shape
chromatin condensation
surface blebs
apoptotic bodies